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University of Central Florida University of Central Florida
STARS STARS
Honors Undergraduate Theses UCF Theses and Dissertations
2019
Role of Spatial Ability in Musical Instrument Choice: Implications Role of Spatial Ability in Musical Instrument Choice: Implications
for Music Education for Music Education
Tevis L. Tucker University of Central Florida
Part of the Music Education Commons, and the Psychology Commons
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Recommended Citation Recommended Citation Tucker, Tevis L., "Role of Spatial Ability in Musical Instrument Choice: Implications for Music Education" (2019). Honors Undergraduate Theses. 602. https://stars.library.ucf.edu/honorstheses/602
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ROLE OF SPATIAL ABILITY IN MUSICAL INSTRUMENT CHOICE:
IMPLICATIONS FOR MUSIC EDUCATION
by
TEVIS L. TUCKER
A thesis submitted in partial fulfillment of the requirements
for the Honors in the Major Program in Psychology
in the College of Sciences
and in the Burnett Honors College
at the University of Central Florida
Orlando, Florida
Spring Term
2019
Thesis Chair: Valerie K. Sims, PhD
ii
© 2019 Tevis L. Tucker
iii
ABSTRACT
The intent of this thesis is to explore the relationship between spatial ability and the wide range
of musical instruments musicians play. Existing literature has established a link between
musicianship and improved spatial ability, but researchers have yet to look at how the spatial
makeup of different musical instruments may, in turn, reveal unique levels of spatial proficiency
from one instrumentalist to the next. This study was formatted as an online survey that included
a music experience scale, a demographics scale, and two measures of spatial ability: the Card
Rotations Test (CRT) and the Paper Folding Test (PFT). Participants who played larger
instruments were hypothesized to score higher on the spatial ability tests. Results show that
specific musical instruments score differently on spatial ability measures, and large instruments
like the piano and marimba consistently outperform smaller instruments. This largely exploratory
study attempts to show that the psychological discipline as a whole should reevaluate how it
categorizes and studies musicians. Furthermore, these preliminary findings will encourage better
practice for how music educators handle the musical instrument selection process, hopefully
leading to a more long-term, student-centered approach.
iv
ACKNOWLEDGMENTS
I would like to thank Dr. Valerie Sims for her unwavering support and infectious passion
throughout my undergraduate career. Without her guidance, my journey to graduate school
would not be possible. I would also like to thank Dr. Matthew Chin and Dr. Scott Lubaroff for
their help and belief in my work. This study would not be the same without your expertise and
shared passion for a better future for music education.
I would like to thank Ms. Karen Cox for helping me find my way at UCF. I spent the
majority of my first two years on campus lost, but I will never forget stepping into your office
for the first time. Thank you for everything.
I would like to thank my grandparents, Nana and Poppy, for making my opportunities at
UCF a possibility. From growing up idolizing the Knights, to getting to walk across the stage as
a graduate, it is all only possible with your love and support. Thank you.
I would like to thank my parents, Tim and Donna, for raising me with an unparalleled
amount of love and support. Everything you did for me helped me get to this point, and I am
forever grateful for that. Never forget that. Thank you, from the bottom of my heart. To Trey and
Cosmo, I love you more than you will ever know.
I would like to thank my best friend, Matt, for being a rock for me these past nine years.
Our long talks, and infinite amount of shared experiences, always reminded me of who I was,
what I loved, and eventually, what I wanted to do with my life. I owe you everything.
I would lastly like to thank my girlfriend, Kait, for the endless amount of support she has
given me during this past year. Thank you for always being there and for always being the
amazing person you are. You inspire me every single day. Thank you for being you.
v
TABLE OF CONTENTS
LIST OF FIGURES ...................................................................................................................... vii
INTRODUCTION .......................................................................................................................... 1
Overview ..................................................................................................................................... 1
Music and the Brain .................................................................................................................... 1
Spatial Ability ............................................................................................................................. 3
Music Education Today .............................................................................................................. 4
Current Research and Hypothesis ............................................................................................... 6
METHOD ....................................................................................................................................... 8
Participants .................................................................................................................................. 8
Procedure ..................................................................................................................................... 9
Materials .................................................................................................................................... 10
Demographics Scale .............................................................................................................. 10
Music Experience Scale......................................................................................................... 10
Card Rotations Test (CRT) .................................................................................................... 10
Paper Folding Test (PFT) ...................................................................................................... 11
RESULTS ..................................................................................................................................... 12
Card Rotations Test (CRT) ....................................................................................................... 12
Paper Folding Test (PFT) .......................................................................................................... 13
Additional Results ..................................................................................................................... 14
DISCUSSION ............................................................................................................................... 16
APPENDIX A: DEMOGRAPHICS SCALE................................................................................ 20
APPENDIX B: MUSIC EXPERIENCE SCALE ......................................................................... 22
vi
REFERENCES ............................................................................................................................. 28
vii
LIST OF FIGURES
Figure 1: Basic Hornbostel-Sachs Breakdown ............................................................................... 8
Figure 2: Specified Hornbostel-Sachs Breakdown ......................................................................... 8
Figure 3: Primary Instrument Frequencies Breakdown .................................................................. 9
Figure 4: Card Rotations Test Example Question ........................................................................ 11
Figure 5: Paper Folding Test Example Question .......................................................................... 11
Figure 6: One-Way ANONA on Specified Hornbostel-Sachs Classification .............................. 13
1
INTRODUCTION
Overview
Music has been shown to have very strong relationships with a plethora of cognitive
processes. One of these processes is spatial ability (e.g., Lee, 2012; Perham, Lewis, Turner, &
Hodgetts, 2014; Pietsch & Jansen, 2012; Sluming, Brooks, Howard, Downes, & Roberts, 2007).
Currently, researchers have yet to look at how specific musical instrumentation may play a role
in a musician’s proficiency at spatial ability. Furthermore, research assumes that this relationship
between music and spatial ability only goes one way (music strengthening spatial skills). This
study aims to shed light on these gaps in the literature and will examine how these findings could
impact the current state of music education.
Music and the Brain
Psychologists have seemingly always had a fascination with music’s role in the human
experience. In recent years, the study of music has shifted mostly into the realm of cognitive
neuroscience, where cutting-edge brain scanning is used to give us a glimpse into the wonders of
music. While each study has its own unique contribution to the literature, the field as a whole is
largely looking at how music enriches other aspects of human cognition.
Music is well known for strengthening the brain, mentally and physically. For example,
keyboard players have been shown to have a higher volume of gray matter in many areas of the
brain, but most notably the cerebellum (Gaser & Schlaug, 2003; Hutchinson, Lee, Gaab, &
Schlaug, 2003; Pascual-Leone, 2001). This can be attributed to the immense motor skills
required when playing a keyboard instrument. Beyond physically restructuring the brain, formal
music training is positively associated with “sustained attention, visual-motor coordination,
2
visual scanning ability, visual processing speed, spatial memory, and information manipulation
skills,” which all involve some aspect of working memory (Suárez, Elangovan, & Au, 2016).
Schellenberg (2006) showed a long-term causality between individuals who take music
lessons and their increased performance on IQ tests. These findings have been backed up for
verbal and non-verbal intelligence over the years. Musicians exhibit higher verbal reasoning and
verbal working memory (Brandler & Rammsayer, 2003; Hansen, Wallentin, & Vuust, 2013); and
for non-verbal reasoning, we also see substantial improvements (see Spatial Ability to read
more).
Researchers have also aimed to distinguish between learned and born traits of
musicianship. Trehub (2001) has shown that infants possess the fundamentals needed for
melodic and rhythmic recognition, as displayed in their ability to distinguish between the pitch
and cadence of each parent’s voice. This study shows that all infants start with an innate
understanding for the frameworks of music, but these findings are rarely supported when
extended beyond listening, or beyond infancy. When looking at pre-existing neural, cognitive,
and motor functions in 5 to 7-year old’s, children who participate in music show no differences
in brain function from their peers (Norton et al., 2005).
These studies suggest that while basic musical traits are innate, there is no clear genetic
advantage that breeds musicians. Trainor (2005) states there are “multiple pathways” to gaining
sufficient levels of musical experience, regardless of age. Again, while the majority of the
literature insists that music increases cognitive functions, more recent findings suggest that
cognitive functions can help a student’s experience with music. Tezer, Cumhur, & Hürsen’s
2016 study on spatial-temporal reasoning illustrates this concept beautifully by stating: “children
with advanced cognitive skills are better at perceiving music and improving it.”
3
Spatial Ability
According to Linn & Petersen (1985), spatial ability can be vaguely defined as the “skill
in representing, transforming, generating, and recalling symbolic, nonlinguistic information.”
Spatial ability is generally split into three categories: spatial perception, mental rotation, and
spatial visualization. These definitions and categorizations are still used throughout the field
today and are included many current meta-analyses (e.g., Voyer & Jansen, 2017).
For context, one of the most notable and controversial links between spatial ability and
music, simply known as the “Mozart effect,” claimed that by listening to Mozart, scores on
spatial ability tasks could be improved (e.g., Rauscher et al., 1993). It did not take much time
before the mainstream media took these findings and began falsely claiming that listening to
classical music boosts IQ scores. While the Mozart effect has since failed to be replicated, has
been criticized for its flawed research design, and has been grossly over-generalized, this study
did pave the way for many researchers to investigate the true relationship that exists between
spatial ability and music (Chablis, 1999).
While the Mozart craze focused on listening to music, recent findings are uncovering that
playing music is where the real magic happens. Sluming et al. (2007) showed orchestral
musicians performed significantly better on mental rotation tasks than a non-musician control
group. Additionally, these findings were supported when comparing musicians to purely
academic students and student-athletes (Pietsch & Jansen, 2012). Lee (2012) continued this
research by theorizing that the spatial nature of reading musical notation may be an underlying
factor for why musicians seem to outperform their peers. This stems from the idea that musical
notation has many spatial properties (e.g., notes higher on the staff being higher in pitch). Lee
4
(2012) supported his hypothesis by finding that the high note-reading group made fewer errors
on spatial tasks than their low-note reading counterparts.
Before going deeper into this area of research, it is important to note that sex differences
in mental rotation tasks have been documented early on in spatial ability meta-analyses (Linn &
Petersen, 1985; Voyer, Voyer, & Bryden, 1995). Males slightly outperform females on most
measures of spatial ability. Recent research, like Uttal et al. (2013), has shown that spatial skills
are malleable and can be improved regardless of sex or age. These recent findings suggest that
sex differences in the field of spatial ability are not as permanent or prominent as they were once
believed to be.
In music, we also see sex differences in terms of musical instrument choice (Harrison,
2007). Smaller, higher-pitched, instruments (e.g., the flute and clarinet) are strongly preferred by
girls, while larger, lower-pitched, instruments (e.g., the drums and trombone) are strongly
preferred by boys (Hallam, Rogers, & Creech, 2008). A literature review on these sex-based
instrument selections states that many factors go into these stereotypes, like gender norms, self-
identity, peer pressure, pop culture influences, classroom demonstrations, and more (Eros, 2008).
Unfortunately, unlike recent changes in the field of spatial ability, we do not see signs of
improvement within these trends in the near future (Abeles, 2009).
Music Education Today
According to Eros (2008), musical instrument choice is one of the most important factors
in a student’s music education experience. This statement seems obvious but is often overlooked
in reality. This phase is commonly a child’s first experience in a formal music environment and
has important implications on how the student will continue with music (McPherson &
Davidson, 2006). But because of our mishandling of this process, we have extremely low
5
retention rates with students continuing music throughout their schooling (Chen & Howard,
2004).
When 23 middle school students are asked why their peers do not continue band in high
school, they state that the students are making a conscious effort to avoid music, rather than
choosing to pursue other options (Gouzouasis, Henrey, & Belliveau, 2008). When 50 band
directors are asked the same question, “lack of commitment to work” was the most common
reason listed (Boyle, DeCarbo, & Jordan, 1995). Regardless of the perspective, it is clear that
music inadvertently turns away more people, than it retains.
The middle school instrument selection process has always been messy. When surveying
322 beginning band directors, Bayley (2004) looked into the specifics. Band directors often
intentionally exclude certain instruments from student selection because of availability or
popularity, already limiting potential “best matches” with these instruments for certain students.
95.2% of directors admit to guiding their students through the selection process, but mostly for
the purposes of balanced instrumentation. Students then commonly try playing instruments to see
which ones they sound best at (before any instruction has started). Finally, students often write a
top 3 list of instruments, and then the band director sorts through these until the ensemble is
filled (Bayley, 2004).
Already, we can see potential problems with these methods. For starters, other than the
illusion of free choice, these tactics are more “band-centered” than “student-centered.” Of
course, there is a good reason why these practices are a necessary evil for music education; a
middle school band composed of all trumpet players is not much of a band in the conventional
sense. Additionally, most factors used in selection only concern the short-term success of the
student and the band. Poor instrument pairings and high dropout rates are far from a long-term
6
sustainability plan. Furthermore, a student’s initial sound it attempts to make on the instrument
should not hold the weight that it does in the audition process. Music educators are more than
equipped to teach their students, but by trying to place students on instruments that they, by
chance, make decent sounds on is just a shortcut down a path with no destination.
Ideally, matching students to instruments their brain is more adept at mastering, therefore
making the student more likely to stick with it and enjoy it, may offer a refreshing change of
pace to the music education community. The current study will aim to provide evidence that the
instrument a musician plays is directly related to their performance on spatial ability tasks. The
better we understand the differences that exist between different types of musicians, the better
we will be able to identify which musician is best suited for each instrument. Beyond that, the
more we uncover about how the brain conceptualizes the vastly different spatial layouts of each
instrument, the more the music education community can begin to move towards a different,
more student-centered long-term philosophy to the instrument selection process.
Current Research and Hypothesis
Reforming the musical instrument selection process is the goal, but there is a long road
ahead. The current theory this study is putting forward is: given the unique range of spatial
properties in each musical instrument, pre-existing spatial ability levels in an aspiring musician
may be a strong predictor of long-term musical success on that specific instrumentation.
A huge flaw in previous research is that all instruments are viewed the same. While
implicitly, researchers know instrumentation is important enough to list within a methods
section, explicitly, these unique instruments are rarely analyzed separately in data analysis.
Currently, it is unclear the differences in cognitive processing between a trombonist and a flutist,
a drummer and a saxophonist, and so on.
7
Each instrument has an entirely different structural makeup, and there is good reason to
believe that certain instruments are better suited for some individuals’ brains over others. To best
answer this question, classifying instrument groups becomes an important procedural decision
before moving to the data analysis phase. There are many different ways to separate instrument
groups, but the Hornbostel-Sachs (H-S) Instrument Classification System has become a very
streamlined and effective way to do so. Essentially the system (created in 1914) categorizes
instruments based on how the instrument fundamentally makes its sound (what way the
instrument interacts with the air molecules around them).
The main instrument families are idiophone (sound comes from the instrument itself
vibrating), membranophone (sound comes from an attached membrane vibrating), chordophone
(sound comes from strings vibrating), and aerophone (sound comes from a column of air
vibrating). Specific differences in instruments are then classified further (within these families)
like the Dewey Decimal System, giving every instrument a unique string of numbers. This
current study will look at the Basic H-S Level (the first digit of the instrument identifier; e.g., the
instrument “family”) and a Specified H-S Level (which will be defined as the first three digits of
the instrument identifier). For example, an oboe’s classification would have a Basic H-S Level of
4 for being an aerophone (wind instrument) and a Specified H-S Level of 422 for being a reed
instrument. Its full H-S classification is 422.112 (double-reeded aerophone with keys).
Instrument classification aside, the working hypothesis for this exploratory study is that
musicians that play bigger instruments will score higher on the spatial ability measures. This,
along with many other questions, will be looked into further throughout the course of this study.
8
METHOD
Participants
Young adults (N = 288; 54% female) between the ages of 18-30 (M = 20.90, SD = 2.58)
were asked to complete a short online survey. Participants were recruited locally at the
University of Central Florida (UCF) through emails sent through the music department. Any
student enrolled in at least one music class (regardless of major) during the Spring 2019 semester
was sent the email with information on the survey. Additional participants were recruited beyond
UCF’s campus through two means: 1) all members of the College Band Director’s National
Association (CBDNA) were sent an email from UCF’s Director of Bands asking the directors to
share the study with their students, and 2) the survey was shared via social media to reach other
populations of musicians.
Figure 1: Basic Hornbostel-Sachs Breakdown
This study was interested in looking at formally trained musicians (see instrument
breakdowns in Figure 1 above, Figure 2 below, and Figure 3 on the next page).
Figure 2: Specified Hornbostel-Sachs Breakdown
Aerophone
Chordophone
Membranophone
Idiophone
Brass
Reeds
Flute
Strings
Piano
Drums
Mallets
9
“Formally trained musician” was operationally defined as participants needing to self-
report at least four years of instrumental music experience to be included in the final data
analysis. Participants were also eligible to be removed from the final data set for not following
directions, scoring above or below three standard deviations from the mean on the spatial ability
measures, and taking too much or too little time to finish.
Figure 3: Primary Instrument Frequencies Breakdown
Procedure
Participants completed an online survey questionnaire of approximately 20 minutes in
length. Each participant was first presented with questions on their musical experience, then they
were presented two different types of spatial ability tests adapted from the French Kit (French,
Ekstrom, & Price, 1969): the Card Rotations Test and the Paper Folding Test. These two spatial
10
tests appeared in random order from participant to participant to eliminate any possible ordering
effects. The two spatial tests were separated by a short demographics section to reduce the
chance of cognitive fatigue.
Materials
The online survey was created through Qualtrics. The data from the surveys were entered
into Microsoft Excel and then further analyzed with Statistical Package for the Social Sciences
(SPSS). Specific measures included in the survey can be seen below.
Demographics Scale
This section was five questions long. Basic background questions involving age, sex,
college major, high school, and hometown zip code was asked to the participants. None of this
information was used to identify participants, but rather to combine the data into separate groups
when entering the data analysis phase. To see the full scale, please see Appendix A.
Music Experience Scale
This section was 13 questions long. Questions included what their primary instrument
was, number of instruments they could play, how many years they have been playing, etc. These
questions aimed to categorize participants into varying levels of musical experience, skill, and
instrumentation. Participant responses helped create different sub-groups for data analysis. To
see the full scale, please see Appendix B.
Card Rotations Test (CRT)
The CRT (see example question below) contains ten questions to be completed over the
span of three minutes. The objective of the task is to determine if the one card (shape) on the left
matches any of the eight cards (shapes) on the right. The cards on the right can be rotated
between 0 and 360 degrees, but not flipped, to be considered the same as the card on the left.
11
Participants mark if each of the cards on the right is the same (S) or different (D) from the card
on the left. Multiple answers can be correct for each question. This is a measure of spatial
orientation, one of the most fundamental levels of spatial ability. Spatial orientation primarily
looks at the process of mentally rotating a configuration in space.
Figure 4: Card Rotations Test Example Question
Paper Folding Test (PFT)
The PFT (see example question below) contains ten questions to be completed over the
span of three minutes. A question on the PFT consists of images on the left-hand side depicting
the steps involved in folding a piece of paper and then punching a hole completely through a
portion of that folded paper. On the right-hand side, there will be images of potential “unfolds”
that the steps on the left-hand side would create. These “unfolds” on the right cannot be flipped
or rotated to better match the images on the left. Participants match the “unfold” they believe
was created through the steps on the left. Only one answer is correct for each question. This is a
measure of spatial visualization (which takes the fundamental skills found in spatial orientation
and adds an additional working memory component to manipulate the mental images in space).
Figure 5: Paper Folding Test Example Question
12
RESULTS
Card Rotations Test (CRT)
A series of one-way ANOVAs were conducted on various grouping variables to see how
each musical instrument differed from one another on their performance of the CRT. For all of
these analyses, it will be assumed that the dependent variable is always score on the CRT. For
the sake of brevity, it will be assumed that group names of instruments refer to the group of
musicians that play them (e.g., aerophones refer to aerophone players, pianos refer to pianists).
The first ANOVA compared the effect of Hornbostel-Sachs (H-S) instrument family (one
digit of specification) on CRT score. The results were not significant [F(3,284) = .82, p = .483].
But, when breaking the groups into more specified H-S classifications (three digits of
specification), significant results are found [F(3,284) = 2.43, p = .026]. Post-hocs reveal that
strings score significantly lower than all other groups except membranophones (LSD ps for mean
differences < .05) and pianos score significantly higher than membranophones and reeds (LSD
ps for mean differences < .05).
To further explore the instrument size hypothesis, motor skill type and clef type were
used to explore how instrument size may impact performance on spatial tasks. For motor skill
type, instruments were separated into two groups: fine motor only or fine/gross motor
combination. When running an ANOVA comparing the effect of motor skill type on CRT score,
no significant results were found [F(1,286) = .242, p = .623]. For clef type, instruments were
separated into four groups: bass clef, treble clef, alto clef, or multiple clefs. An ANOVA
comparing clef type on CRT score yielded significant results [F(3,284) = 2.95, p = .033], and
post-hocs displayed that multiple clef group scored significantly higher than the treble and alto
clef groups (LSD ps for mean differences < .05).
13
Paper Folding Test (PFT)
A series of one-way ANOVAs were conducted on various grouping variables to see how
each musical instrument differed from one another on their performance of the PFT. For all of
these analyses, it will be assumed that the dependent variable is always score on the PFT. For the
sake of brevity, it will be assumed that group names of instruments refer to the group of
musicians that play them (e.g., aerophones refer to aerophone players, pianos refer to pianists).
The first ANOVA compared H-S instrument family (one digit of specification) to PFT
score. Significant results were found [F(3,284) = 2.93, p = .034] and post-hocs showed that
chordophones significantly outscored aerophones (LSD p for mean difference = .011).
Furthermore, breaking the groups into smaller H-S classifications (three digits of specification)
to compare their effect on PFT score yielded significant results as well [F(3,284) = 2.29, p =
.036]. Post-hocs show that idiophones score higher than reeds (LSD p for mean difference =
.012) and pianos score higher than reeds and brass (LSD ps for mean differences > .05).
Figure 6: One-Way ANONA on Specified Hornbostel-Sachs Classification
4.5
5
5.5
6
6.5
7
7.5
8
8.5
Brass Reeds Flute Strings Piano Drums Mallets
Sco
re o
n P
FT
Instrument Group
H-S Classification (3 Digits)
14
To further explore the instrument size hypothesis, motor skill type and clef type were
used to explore how instrument size may impact performance on spatial tasks. An ANOVA
comparing motor skill type (fine motor only vs. fine/gross motor combination) with PFT score
showed significant results [F(1,286) = 8.59, p = .004] with the fine/gross combination group
scoring higher (M = 7.14, SD = 1.97) than the fine only group (M = 6.36, SD = 2.27). An
ANOVA comparing clef type (bass vs. treble vs. alto vs. multiple clefs) with PFT score found no
significant results [F(3,284) = 2.18, p = .091].
Additional Results
To help discover more about the potential directionality of music improving spatial skills
(within the limits of this study’s non-experimental design), self-reported years of experience was
used as an independent variable to see how duration of time with music might impact
performance on spatial tasks. No significant results were found when ANOVAs were ran
comparing years of experience to CRT [F(6,281) = 1.65, p = .133] or PFT [F(6,281) = 1.09, p =
.368]. How many instruments participants could play was also used as an independent variable to
help explore this question, but it also did not show any significant results either for CRT
[F(8,279) = 1.48, p = .165] or PFT [F(8,279)= 1.60, p = .125].
Reading musical notation has been shown in previous research to be spatial in nature, so
the current study used self-reported sight-reading proficiency as an independent variable to look
at its relationship with spatial ability performance. No significant results were found on
performance of the CRT [F(5,281) = 1.27, p = .277] or PFT [F(5,281) = 2.02, p = .075]. Because
of sex differences being cited in the literature, demographic variables were also explored further.
Age and sex were looked at, but no significant differences were uncovered, implying that these
factors did not heavily influence the results on the CRT or PFT. Finally, as an internal validity
15
check, a Pearson correlation was run to show that scores on the CRT and PFT were positively
correlated within each participant (r = .31, p < .001).
16
DISCUSSION
Spatial performance on the Specified Hornbostel-Sach’s (H-S) classification (3 digits of
specification) was significant for the Card Rotations Test (CRT) and the Paper Folding Test
(PFT). This supports our underlying theory that unique instrumentation among musicians elicits
unique levels of spatial ability. But when stepping back and only looking at the instrument
“family” that a musician belongs to (defined as the Basic H-S classification), there are only
significant differences on the PFT, but not on the CRT. The additional workload that the PFT
and spatial visualization require (adding working memory) could explain why these results start
to become apparent at a broader stage in musical instrument classification process. The PFT may
be a more robust measure of spatial ability among the music community, which suggests that
differences within wind, string, and percussion players are shared at a broader level, before even
getting to the unique instrumentation in each instrument “family.”
This difference in performance on each spatial ability test is not entirely surprising given
that these tests measure slightly different aspects of spatial ability (CRT measuring spatial
orientation and PFT measuring spatial visualization). This study tried to cast a broad stroke on
this topic, but narrowing this research question down to one specific measure of spatial ability
seems to be necessary when moving forward with future research. When considering the spatial
layout of a musical instrument, and the fact that playing a musical instrument is an active and
dynamic experience, focusing on the musician’s performance of the PFT seems like the most
applicable spatial measure to look at in future studies. This additional working memory
component (i.e., the mental holding and manipulation of objects) seems to be important in the
musical instrument experience (Suárez et al., 2016).
17
The big takeaway from this study is that, yes, there are differences that exist when
looking at musicians by the instrument they play, not just the general label they share as
“musicians.” These preliminary findings provide evidence of fundamental differences that
musical instruments have on specific cognitive tasks (i.e., spatial ability). Furthermore, the
exploratory hypothesis of larger instruments scoring better on spatial ability tasks seems to
explain some of these findings. The piano and idiophones (instruments like the marimba) are the
largest instruments in the sample, and their performance on spatial ability tasks was consistently
among the top scores on the CRT and PFT.
But, instrument size becomes an ambiguous subject as we start looking into other
instruments. The size alone does not inherently mean that the performer utilizes the entirety of
that space to play a said instrument. The tuba, for example, is the largest brass instrument, but
the performer only has to worry about utilizing a set of valves that are relatively close in
proximity to them. This is similar to many valved brass instruments, providing evidence that the
size of the instrument does not directly determine its spatial properties. Another factor, or
factors, should be looked at when we talk about the spatial nature of musical instruments.
Potential factors could include hand distance from the body, hand movement from a general
“home base” position, or specific hand utility in the playing process.
The current study was also interested in exploring other aspects of musical instrument
playing— beyond the physical realm. Each participant’s self-reported sight-reading ability was
looked at, but there was no significant relationship to their performance on spatial ability tasks.
Though Lee (2012) has documented the spatial nature of reading musical notation, our finding
suggests that there are different underlying cognitive processes at play between everyday note
reading and the ability to sight-read during a condensed timeframe. It is also worth noting that
18
the current study did not find any significant sex differences on spatial ability tasks. This
supports recent spatial ability literature and adds to the body of evidence suggesting that sex
differences may be disappearing from spatial tasks altogether (e.g. Uttal et al. 2013).
The results also shed light on the “chicken-egg” debate among researchers, on whether
music strengthens the brain or if a stronger brain increases musical ability. This directionality
often supports the notion that music positively affects various cognitive processes (laying the
foundation for the wide range of claims arguing that music enriches other aspects of our lives).
The current study looked at years of experience, but found no significant effect on spatial ability
performance. Given the correlational nature of this study, our results lack definitive causality, yet
multiple inferences can still be drawn and provide unique context to this directionality debate.
One interpretation could be that any benefits that music provides to spatial skills take
place during an individual’s initial experience with music. The current study was only interested
in formally trained musicians with at least four years of musical experience. Any growth that
may take place before this timeframe would go undetected unless an additional sample of
musicians with less experience were included in the final data analyses. Another interpretation
could imply that music itself is not what strengthens spatial skills. It is possible that individuals
that are already high in spatial ability seek out music, or are the ones that “stick with it,”
compared to individuals that are predisposed with lower levels of spatial ability.
In closing, this study helps open the door for future research, but independently, this
study is just a small voice in the music and psychology community. Future studies should
explore using experimental (for the purposes of causality) and longitudinal (for the purposes of
increased control) designs to build upon these questions and substantiate some of these claims on
a larger scale. If for nothing else, this research (like many others) hopes to start a conversation.
19
Researchers and music educators need to continue to work together to better understand
this thing we call music. Whether it is our categorization of musicians as psychologists or our
approach to instrument selection as music educators, there is room for improvement in both
fields. Studying individual differences among various musical instruments adds a unique
perspective to music and psychology literature, but most importantly, lays the foundation for
bringing order to a frequently disorderly musical instrument selection process.
This research represents, what we believe is, the “tip of the iceberg” to a plethora of
soon-to-be-discovered links that exist between various cognitive processes and their role from
one musical instrument to the next. We must rethink our conventional notions about how we try
to attack music’s biggest questions. Throwing together all of the unique sounds of an orchestra
into one room, with no rhyme or reason, will never let us hear the music, only noise. As we
tackle these questions, we must take it one instrument and one cognitive process at a time—
listening to the unique and distinct melodies that each musical instrument creates. Once we
understand each part of the score, only then will we be able to piece everything back together
and hear a beautiful, harmonious masterpiece.
20
APPENDIX A: DEMOGRAPHICS SCALE
21
Demographics Scale
What is your age? ________
What is your sex?
Male
Female
Prefer not to answer
What is your college major? (Please write as it appears on a degree audit) ________________
What high school did you attend? (Please write out the full name) ________________
What is the 5-digit zip code of your hometown? ________________
22
APPENDIX B: MUSIC EXPERIENCE SCALE
23
Music Experience Scale
How many different instruments can you proficiently play?
***Proficiency will be defined as being able to play all 12 major scales or a similar level of
instrument-specific mastery. For example, if you were asked to play it right now, you would be
able to navigate around the instrument fairly smoothly given your experience with the instrument
***Percussionists: any pitched percussion instruments should be combined together to count as
(1) type of instrument, and any non-pitched percussion instruments should be combined together
to count as (1) type of instrument. Being able to play pitched and non-pitched percussion
instruments (no matter how many of each) should account for no more than (2) instruments in
your total instrument tally
1
2
3
4
5
6
7
8
9
10 or more
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Please list out below the instruments you reported you could proficiently play (please spell as
accurately as possible)
______________________________________________________________________________
______________________________________________________________________________
______________________________________________________________________________
What is the primary instrument you play?
______________________________________________________________________________
Why do you consider that instrument your primary instrument? Please limit your
response to a few sentences
________________________________________________________________________
________________________________________________________________________
________________________________________________________________________
Is your primary instrument the same instrument you first started on?
Yes
No
If not, describe why you made the switch from that first instrument?
________________________________________________________________________
25
How many total years have you been formally playing musical instruments?
***Formally will denote when you first took private lessons, were in a band class, or could play
your first instrument at a relatively proficient level
Less than 4 years
4 years
5 years
6 years
7-9 years
10-12 years
13-15 years
More than 15 years
Compared to other musicians with a similar level of musical ability (that also play your primary
instrument), how would you self-rank your sight-reading ability on a scale from 1-7?
1 Low sight-reading proficiency
2
3
4 Average sight-reading proficiency
5
6
7 High sight-reading proficiency
26
Did you ever stop playing music (at any age) for an extended period of time because of
dissatisfaction with your instrument?
Yes
No
If you were involved in middle school band, please select how positive your experience was. If
you were not involved in middle school band, please select “I was not in middle school band”.
Very negative
Somewhat negative
Neutral
Somewhat positive
Very positive
I was not in middle school band
If you were involved in high school band, please select how positive your experience was. If you
were not involved in high school band, please select “I was not in high school band”.
Very negative
Somewhat negative
Neutral
Somewhat positive
Very positive
I was not in high school band
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Have you ever participated in a season of drum corps (DCI or DCA) while playing a marching
instrument? Respond “Not a marching member” if participation in drum corps was exclusively in
pit, colorguard, or as drum major.
Yes
No
Not a marching member
Please describe, in a few sentences, how you selected your first musical instrument. If someone
else (e.g., a band director, a parent, a friend) was involved in this decision, please include their
role and any other relevant information on the topic. Be detailed, but concise when responding.
Don’t take more than a couple of minutes to write a response.
______________________________________________________________________________
______________________________________________________________________________
______________________________________________________________________________
Please answer, in a few sentences, if you think there is a better way to “audition” students on
their first instrument in the middle school setting (based on your experience). Feel free to
elaborate on the pros/cons of the process you are familiar with. Be detailed, but concise when
responding. Don’t take more than a couple of minutes to write a response.
______________________________________________________________________________
______________________________________________________________________________
______________________________________________________________________________
28
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